Method for providing telephone services through xdsl connection lines

ABSTRACT

The inventive method uses a VoIP server which provides the classical subscriber performance features of an exchange, and a VoIP client in the integrated access device (IAD) of the subscriber. The VoIP server uses a known VoIP signalling protocol for controlling the VoIP voice transmission between the VoIP client in IAD and the media gateway and for tunnelling the PSTN/ISDN signalling between the VoIP client in the IAD and the VoIP server.

1. WHAT TECHNICAL PROBLEM IS SUPPOSED TO BE SOLVED BY THE INVENTION?

[0001] Alternative local network operators (e.g., COLT) who want to serve end customers directly must introduce new access technologies or lease the subscriber access line from the former monopolist (e.g., Deutsche Telekom). The monthly leasing costs in this connection are in the range of the basic subscriber fee for conventional telephony service, so that the alternative local network operator must offer additional services by way of the leased subscriber access line, in order to be profitable.

[0002] These additional services are based on the xDSL technology and increasingly consist of Voice_over_DSL (VODSL), in addition to broadband Internet access. Using VODSL, the broadband xDSL technology is utilized to make up to 16 subscriber connections for lucrative telephony services (ISDN or analog) available to the end customer, by way of one connection line. The target group for VODSL services is primarily small to medium-size businesses.

2. HOW WAS THIS PROBLEM SOLVED UNTIL NOW?

[0003] In general, packet-oriented methods are used for VODSL, in order to be able to offer the known telephony services (ISDN or analog) by way of xDSL lines. Methods known up to the present are:

I. Broadband Loop Emulation Services (BLES)

[0004] This solution is shown in FIG. 1. In this method, the subscriber signaling protocols (e.g., GR303, V5, ISDN) and the voice channel are transparently carried by a conventional subscriber switching center (Tln-Vst) to the line termination in the Integrated Access Device (IAD) at the end customer location, by way of the packet-oriented access network. In most cases, ATM/AAL2 is used as the transport protocol for the transmission of signal and voice. Other transport protocols, e.g., FR or IP, would also be conceivable.

[0005] Disadvantages of this solution approach are, among others:

[0006] Complicated, error-prone operation, because the subscriber must be set up twice, once at the subscriber switching center and again in the AN.

[0007] Restriction to voice services, i.e., cannot be expanded to multi-media, in spite of the use of a packet-oriented network.

[0008] Advantages of this solution method are, among others:

[0009] Assuring conventional telephony services and subscriber terminations, conventional terminals can continue to be used without restrictions.

[0010] The quality of service (QOS) required for the telephony service is assured by using a dedicated ATM-PVC in the access network and TDM in the subscriber switching center.

II. Voice Over Multi-Service Data Networks (VOMSDN)

[0011] This solution is shown in This method is based on VoIP and utilizes the corresponding protocols, e.g., H323, SIP, MGCP. Access to the conventional PSTN no longer takes place by way of a subscriber switching center, but rather by way of a transit switching center. VoIP controller and media gateway take over the interworking function with regard to signaling (H. 323, SIP⇄ ISUP) and working channel (VoIP⇄ TDM).

[0012] Disadvantages of this solution method are, among others:

[0013] The quality of service (QOS) required for telephony service cannot be assured, since voice, signaling, and data packets are transported by way of the same ATM connection.

[0014] The VoIP telephony service being offered is not identical with conventional telephony service—conventional terminals can only be used within limitations.

[0015] Advantages of this solution method are, among others:

[0016] The possibility of using LANs as a distribution network also for telephony services, at the end customer location.

[0017] Expandability to multi-media services, particularly when using H.323 or SIP.

3. IN WHAT WAY DOES THE INVENTION SOLVE THE INDICATED TECHNICAL PROBLEM?

[0018] The method according to the invention is shown in FIG. 3. The method according to the invention combines the advantages of the known solution methods, while avoiding the specific disadvantages. It can be used in combination with any DSLAMs that are used to make the xDSL access available, and has no influence on the broadband Internet access of the telephone customer.

[0019] The method according to the invention uses a VoIP server that makes the conventional subscriber features of an LE available, and a VoIP client in the IAD. The VoIP server uses a known VoIP signaling protocol (H.323, SIP, etc.) to control the VoIP voice transmission between the VoIP client in the IAD and the MG, and for tunneling the PSTN/ISDN signaling between the VoIP client in the IAD and the VoIP server. The VoIP client in the IAD converts the VoIP voice and the PSTN/ISDN signaling tunneled by way of the VoIP signaling protocol to the conventional voice transmission and signaling methods at the subscriber connection of the IAD (ISDN, analog).

[0020] The method, according to the invention, for making conventional telephony services available by way of VoIP by way of xDSL connection lines is characterized in detail by the following elements:

[0021] 1. The use of two dedicated ATM connections (PVC or SVC) for a) the voice channel and b) the signaling. In this way, the QOS required for telephony services is assured, on the one hand, and voice and signaling can be carried to different network elements, on the other hand.

[0022] 2. The use of VoIP signaling (H.323, SIP, etc.) for controlling voice transmission between the IAD and the MG, on the one hand, and for transparent transmission of the PSTN/ISDN signaling (tunneling) between the IAD and the VoIP controller, on the other hand.

[0023] 3. The use of an MG for converting the voice between VoIP and TDM. This MG is controlled by the VoIP controller. With regard to the wiring of the TDM output of the MG, two configurations are possible.

[0024] 3a. The TDM output of the MG is carried to the VoIP controller. In this configuration, the TDM bearer is processed by the VoIP controller. The advantage of this solution is that a simple (trunking) MG can be used, which only has to be able to handle conversion of the language between the VoIP and the TDM, but no special functions to support subscriber services.

[0025] 3b. The TDM output of the MG is carried directly to the overriding switching center. In this configuration, the TDM bearer is not processed directly by the VoIP controller. Therefore, the MG must also be able to handle functions to support subscriber services, in addition to conversion of the language between the VoIP and the TDM. These are, among others, recognition, feed of tones and announcements, support of multi-channel connections. In addition, the complexity of the MG control protocol is correspondingly greater in this configuration.

[0026] 4. The use of a VoIP controller that a) contains the subscriber data (telephone number, services, etc.), b) handles the PSTN/ISDN signaling, c) determines the call rating data, d) terminates the VoIP signaling protocol and uses it for tunneling of the PSTN/ISDN signaling, e) controls the MG and, if necessary, f) processes the TDM voice channel.

[0027] 5. The use of a VoIP client integrated in the IAD that a) terminates the two ATM connections (SVC or PVC) for voice and signaling, b) converts voice transmission between VoIP and the terminal connection (ISDN or analog), c) terminates the VoIP signaling protocol and uses it for tunneling of the PSTN/ISDN signaling, and d) brings the voice and PSTN/ISDN signaling together and thereby operates the terminal connection for ISDN or analog subscriber terminals at the IAD.

4. WHAT ARE THE PARTICULAR FEATURES OF THE INVENTION?

[0028] A method for making telephony services available by way of VoIP by way of xDSL connection lines, which is characterized by:

[0029] QOS for telephony services by separation of voice and signaling, thanks to dedicated ATM connections (PVC or SVC) for voice transmission (VoIPoATM) and signaling (H.323, SIP, etc.) between the IAD and the VoIP controller or media gateway.

[0030] VoIP controller and corresponding VoIP client in the IAD for tunneling of the PSTN/ISDN signaling by means of VoIP signaling (H.323, SIP, etc.) and control of the voice transmission by way of VoIP.

[0031] Use of a simple (trunking) MG, controlled by the VoIP controller, to convert the working channel between VoIP (for transport by way of ATM and xDSL) and TDM (for processing in the VoIP controller and connection to conventional switching centers).

[0032] Abbreviations used:

[0033] AN: Access Network

[0034] DSL: Digital Subscriber Line

[0035] DSLAM: DSL Access Module

[0036] FR: Frame Relay

[0037] IAD: Integrated Access Device

[0038] IP: Internet protocols

[0039] LE, Tl-Vst: subscriber switching center (Local Exchange)

[0040] MG: Media Gateway

[0041] PVC: Permanent Virtual Connection

[0042] SVC: Switched Virtual Circuit

[0043] VST, Vst: switching center

[0044] VoIP: Voice over IP 

1. Method for making telephony services available by way of xDSL connection lines, according to which a transport protocol connection is used for the voice channel, and another transport protocol connection is used for the signaling, in order to implement a telephony service, VoIP signaling is used to control the voice transmission between the IAD and the MG, on the one hand, and for transparent transmission of the PSTN/ISDN signaling between the IAD and the VoIP controller, a media gateway (MG) is used to convert voice between VoIP and TDM, a VoIP controller is used that a) handles the PSTN/ISDN signaling, b) terminates the VoIP signaling protocol and uses it for tunneling of the PSTN/ISDN signaling, and c) controls the media gateway (MG), an xDSL access device (IAD) is used, by means of which a) the two ATM connections for voice and signaling are terminated, b) the voice transmission between VoIP and the terminal connection is converted, c) the VoIP signaling protocol is terminated and used for tunneling of the PSTN/ISDN signaling, and d) the voice and PSTN/ISDN signaling are brought together and thereby the terminal connection for the subscriber terminals connected with the xDSL access device (IAD) is operated.
 2. Telephony service system, with a VoIP server that makes the conventional subscriber features of a subscriber switching center available, an xDSL access device (IAD) that contains at least one subscriber connection, and that converts the VoIP voice and the PSTN/ISDN signaling tunneled by way of the VoIP signaling protocol to the conventional voice transmission and signaling methods at a subscriber connection, a media gateway that converts the voice between VoIP and TDM, wherein the VoIP server uses a known VoIP signaling protocol (H.323, SIP, etc.) to control the VoIP voice transmission between the xDSL access device (IAD) and the media gateway and for tunneling the PSTN/ISDN signaling between the xDSL access device (IAD) and the VoIP server.
 3. VoIP server that makes the conventional subscriber features of a subscriber switching center available, that uses a known VoIP signaling protocol to control the VoIP voice transmission between the xDSL access device (IAD) and the media gateway, and for tunneling the PSTN/ISDN signaling between itself and the xDSL access device (IAD).
 4. xDSL access device that terminates the two transport protocol connections for voice and signaling, converts the voice transmission between VoIP and the terminal connection, terminates the VoIP signaling protocol and uses it for tunneling the PSTN/ISDN signaling, brings the voice and PSTN/ISDN signaling together and thereby operates the terminal connection for subscriber terminals.
 5. Media gateway that converts the voice between VoIP and TDM and is controlled by a VoIP controller, characterized in that the TDM output of the MG is carried to the VoIP controller. [see original for figures] FIG. 1Teilnehmerseite=subscriber side Netzseite=network side Sprache & . . . ATM=voice and signaling by way of ATM Sprache & . . . =voice and signaling Daten=data breitbandiger . . . =broadband Internet access klassische . . . =conventional telephony services Tln-Vst=Teilnehmer-Vermittlungsstelle=subscriber switching center FIG. 2Sprache & . . . IP=voice and signaling by way of IP Sprache fiber . . . =voice over IP, TDM Signalisierung . . . signaling over IP breitbandiger . . . =broadband Internet access Vst=Vermittlungsstelle=switching center FIG. 3klassische . . . =conventional telephony services üfber=by way of Signalisierung=signaling Sprache=voice Sprache & . . . ATM=voice and signaling by way of ATM Daten=data breitbandiger . . . =broadband Internet access Transit-Vst=Transit-Vermittlungsstelle=transit switching center 